Efficient preparation of microtip arrays for atom probe tomography using fs-laser processing

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Efficient preparation of microtip arrays for atom probe tomography using fs-laser processing. / Tkadletz, Michael; Waldl, Helene; Schiester, Maximilian et al.
in: Ultramicroscopy, Jahrgang 246.2023, Nr. April, 113672, 04.2023.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Vancouver

Tkadletz M, Waldl H, Schiester M, Lechner A, Schusser G, Krause M et al. Efficient preparation of microtip arrays for atom probe tomography using fs-laser processing. Ultramicroscopy. 2023 Apr;246.2023(April):113672. Epub 2022 Dez 29. doi: 10.1016/j.ultramic.2022.113672

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@article{76a9be05d0e94fa5a8ee7ce0271419c3,
title = "Efficient preparation of microtip arrays for atom probe tomography using fs-laser processing",
abstract = "Microtip arrays, also called microtip coupons, are routinely used in atom probe tomography (APT) as specimen carriers. They are commercially available consumables, usually made of Si with high electrical conductivity, produced via dedicated shaping techniques. Their purpose is to act as a specimen mount after focused ion beam (FIB) based lift-out procedures. Within this work, an alternative approach to prefabricated microtip coupons is presented, by directly creating a microtip array on the sample to be investigated utilizing fs-laser processing. An exemplary array of microtip posts was fs-laser processed from a TiN coating on Si substrate and subjected to final preparation via annular FIB milling. Subsequently, APT specimen of the TiN coating as well as of the Si substrate were successfully measured in laser assisted mode, using a commercial local electrode APT system. To further emphasize the versatility of the proposed approach, additional voltage measurements of highly conductive B doped Si arrays as well as exemplarily fs-laser processed microtip arrays of various other materials are provided as supplementary material to this article. The presented methodology bypasses the lift-out and avoids the necessity of a Pt weld between specimens and coupon posts which is frequently considered to represent a weak spot. It reduces consumables consumption and provides a high number of specimens in short time, while it is applicable for a wide range of materials and has thus the potential to revolutionize APT specimen preparation.",
author = "Michael Tkadletz and Helene Waldl and Maximilian Schiester and Alexandra Lechner and Georg Schusser and Michael Krause and Nina Schalk",
note = "Publisher Copyright: {\textcopyright} 2022",
year = "2023",
month = apr,
doi = "10.1016/j.ultramic.2022.113672",
language = "English",
volume = "246.2023",
journal = "Ultramicroscopy",
issn = "0304-3991",
publisher = "Elsevier",
number = "April",

}

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TY - JOUR

T1 - Efficient preparation of microtip arrays for atom probe tomography using fs-laser processing

AU - Tkadletz, Michael

AU - Waldl, Helene

AU - Schiester, Maximilian

AU - Lechner, Alexandra

AU - Schusser, Georg

AU - Krause, Michael

AU - Schalk, Nina

N1 - Publisher Copyright: © 2022

PY - 2023/4

Y1 - 2023/4

N2 - Microtip arrays, also called microtip coupons, are routinely used in atom probe tomography (APT) as specimen carriers. They are commercially available consumables, usually made of Si with high electrical conductivity, produced via dedicated shaping techniques. Their purpose is to act as a specimen mount after focused ion beam (FIB) based lift-out procedures. Within this work, an alternative approach to prefabricated microtip coupons is presented, by directly creating a microtip array on the sample to be investigated utilizing fs-laser processing. An exemplary array of microtip posts was fs-laser processed from a TiN coating on Si substrate and subjected to final preparation via annular FIB milling. Subsequently, APT specimen of the TiN coating as well as of the Si substrate were successfully measured in laser assisted mode, using a commercial local electrode APT system. To further emphasize the versatility of the proposed approach, additional voltage measurements of highly conductive B doped Si arrays as well as exemplarily fs-laser processed microtip arrays of various other materials are provided as supplementary material to this article. The presented methodology bypasses the lift-out and avoids the necessity of a Pt weld between specimens and coupon posts which is frequently considered to represent a weak spot. It reduces consumables consumption and provides a high number of specimens in short time, while it is applicable for a wide range of materials and has thus the potential to revolutionize APT specimen preparation.

AB - Microtip arrays, also called microtip coupons, are routinely used in atom probe tomography (APT) as specimen carriers. They are commercially available consumables, usually made of Si with high electrical conductivity, produced via dedicated shaping techniques. Their purpose is to act as a specimen mount after focused ion beam (FIB) based lift-out procedures. Within this work, an alternative approach to prefabricated microtip coupons is presented, by directly creating a microtip array on the sample to be investigated utilizing fs-laser processing. An exemplary array of microtip posts was fs-laser processed from a TiN coating on Si substrate and subjected to final preparation via annular FIB milling. Subsequently, APT specimen of the TiN coating as well as of the Si substrate were successfully measured in laser assisted mode, using a commercial local electrode APT system. To further emphasize the versatility of the proposed approach, additional voltage measurements of highly conductive B doped Si arrays as well as exemplarily fs-laser processed microtip arrays of various other materials are provided as supplementary material to this article. The presented methodology bypasses the lift-out and avoids the necessity of a Pt weld between specimens and coupon posts which is frequently considered to represent a weak spot. It reduces consumables consumption and provides a high number of specimens in short time, while it is applicable for a wide range of materials and has thus the potential to revolutionize APT specimen preparation.

UR - http://www.scopus.com/inward/record.url?scp=85145264788&partnerID=8YFLogxK

U2 - 10.1016/j.ultramic.2022.113672

DO - 10.1016/j.ultramic.2022.113672

M3 - Article

VL - 246.2023

JO - Ultramicroscopy

JF - Ultramicroscopy

SN - 0304-3991

IS - April

M1 - 113672

ER -